Permeability and Elastic Properties of Rocks From the Northern Hikurangi Margin: Implications for Slow‐Slip Events

Nicola Tisato; Carolyn D. Bland; Harm VanAvendonk; Nathan Bangs; Hector Garza; Omar Alamoudi; Kelly Olsen; Andrew Gase

doi:10.1029/2023GL103696

Geophysical Research Letters (Jan 2024)

Permeability and Elastic Properties of Rocks From the Northern Hikurangi Margin: Implications for Slow‐Slip Events

Nicola Tisato,
Carolyn D. Bland,
Harm VanAvendonk,
Nathan Bangs,
Hector Garza,
Omar Alamoudi,
Kelly Olsen,
Andrew Gase

Affiliations

Nicola Tisato: Department of Earth and Planetary Sciences Jackson School of Geosciences The University of Texas at Austin Austin TX USA
Carolyn D. Bland: Department of Earth and Planetary Sciences Jackson School of Geosciences The University of Texas at Austin Austin TX USA
Harm VanAvendonk: Jackson School of Geosciences Institute for Geophysics The University of Texas at Austin Austin TX USA
Nathan Bangs: Jackson School of Geosciences Institute for Geophysics The University of Texas at Austin Austin TX USA
Hector Garza: Department of Earth and Planetary Sciences Jackson School of Geosciences The University of Texas at Austin Austin TX USA
Omar Alamoudi: Department of Earth and Planetary Sciences Jackson School of Geosciences The University of Texas at Austin Austin TX USA
Kelly Olsen: Jackson School of Geosciences Institute for Geophysics The University of Texas at Austin Austin TX USA
Andrew Gase: Jackson School of Geosciences Institute for Geophysics The University of Texas at Austin Austin TX USA

DOI: https://doi.org/10.1029/2023GL103696
Journal volume & issue: Vol. 51, no. 2
pp. n/a – n/a

Abstract

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Abstract Fluid flow and pore‐pressure cycling are believed to control slow slip events (SSEs), such as those that frequently occur at the northern Hikurangi margin of New Zealand. To better understand fluid flow in the forearc system we examined the relationship between several physical properties of Cretaceous‐to‐Pliocene sedimentary rocks from the Raukumara peninsula. We found that the permeability of the deep wedge is too low to drain fluids, but fracturing increases permeability by orders of magnitude, making fracturing key for fluid flow. In weeks to months, plastic deformation, swelling, and possibly not‐yet‐identified mechanisms heal the fractures, restoring the initial permeability. We conclude that overpressures at the northern HM might partly dissipate during SSEs due to enhanced permeability near faults. However, in the months following an SSE, healing in the prism will lower permeability, forcing pore pressure to rise and a new SSE to occur.

Published in Geophysical Research Letters

ISSN: 0094-8276 (Print); 1944-8007 (Online)
Publisher: Wiley
Country of publisher: United States
LCC subjects: Science: Physics: Geophysics. Cosmic physics
Website: https://agupubs.onlinelibrary.wiley.com/journal/19448007

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